DNA-mounted self-assembly: new approaches for genomic analysis and SNP detection.

This article presents an overview of new emerging approaches for nucleic acid detection via hybridization techniques that can potentially be applied to genomic analysis and SNP identification in clinical diagnostics. Despite the availability of a diverse variety of SNP genotyping technologies on the diagnostic market, none has truly succeeded in dominating its competitors thus far. Having been designed for specific diagnostic purposes or clinical applications, each of the existing bio-assay systems (briefly outlined here) is usually limited to a relatively narrow aspect or format of nucleic acid detection, and thus cannot entirely satisfy all the varieties of commercial requirements and clinical demands. This drives the diagnostic sector to pursue novel, cost-effective approaches to ensure rapid and reliable identification of pathogenic or hereditary human diseases. Hence, the purpose of this review is to highlight some new strategic directions in DNA detection technologies in order to inspire development of novel molecular diagnostic tools and bio-assay systems with superior reliability, reproducibility, robustness, accuracy and sensitivity at lower assay cost. One approach to improving the sensitivity of an assay to confidently discriminate between single point mutations is based on the use of target assembled, split-probe systems, which constitutes the main focus of this review.

Detection of nucleic acids in situ: novel oligonucleotide analogues for target-assembled DNA-mounted exciplexes.

This research describes the effects of structural variation and medium effects for the novel split-oligonucleotide (tandem) probe systems for exciplex-based fluorescence detection of DNA. In this approach the detection system is split at a molecular level into signal-silent components, which must be assembled correctly into a specific 3-dimensional structure to ensure close proximity of the exciplex partners and the consequent exciplex fluorescence emission on excitation. The model system consists of two 8-mer oligonucleotides, complementary to adjacent sites of a 16-mer DNA target. Each probe oligonucleotide is equipped with functions able to form an exciplex on correct, contiguous hybridization. This study investigates the influence of a number of structural aspects (i.e. chemical structure and composition of exciplex partners, length and structure of linker groups, locations of exciplex partner attachment, as well as effects of media) on the performance of DNA-mounted exciplex systems. The extremely rigorous structural demands for exciplex formation and emission required careful structural design of linkers and partners for exciplex formation, which are here described. Certain organic solvents (especially trifluoroethanol) specifically favour emission of the DNA-mounted exciplexes, probably the net result of the particular duplex structure and specific solvation of the exciplex partners. The exciplexes formed emitted at approximately 480 nm with large Stokes shifts ( approximately 130-140 nm). Comparative studies with pyrene excimer systems were also carried out.

An exciplex-based, target-assembled fluorescence system with inherently low background to probe for specific nucleic acid sequences.

A novel detection technique, called ExciProbes, has been developed to proof-of-principle level for DNA oligonucleotides. The new approach is based on the use of two short oligonucleotides complementary to a target nucleic acid sequence. Each short-probe oligonucleotide bears the separated parts of a new class of fluorescence detector, an exciplex. These isolated parts of the detector have no inherent signal at the detection wavelength. They are designed to detect biotarget by being assembled by the target itself to give a new molecular entity (the exciplex), with a characteristic fluorescence and very large Stokes shift (typically >150 nm). The technique is not related to fluorescence resonance energy transfer, and can potentially resolve to 1 base pair. ExciProbes can detect single or double mutations in a short sequence of DNA, and can be combined with temperature-filtering to provide allelic discrimination of single nucleotide polymorphism analysis. Compared to other fluorophore systems that have large backgrounds (typically >60%), ExciProbes show backgrounds of <1% under comparable conditions, and can be used with DNA, RNA, or synthetic nucleic acids such as locked nucleic acid.